Rare-earth oxide based coatings based on ion assisted deposition

ABSTRACT

A component for a semiconductor processing chamber includes a ceramic body having at least one surface with a first average surface roughness of approximately 8-16 micro-inches. The component further includes a conformal protective layer on at least one surface of the ceramic body, wherein the conformal protective layer is a plasma resistant rare earth oxide film having a substantially uniform thickness of less than 300 μm over the at least one surface and having a second average surface roughness of below 10 micro-inches, wherein the second average surface roughness is equal to or less than the first average surface roughness.

RELATED APPLICATIONS

This patent application is a continuation application of U.S. patent application Ser. No. 14/034,315, filed Sep. 23, 2013, now U.S. Pat. No. 9,583,369, which claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 61/856,696, filed Jul. 20, 2013, both of which are incorporated by reference herein.

TECHNICAL FIELD

Embodiments of the present invention relate, in general, to a method of coating chamber components with a thin film plasma resistant protective layer using ion assisted deposition.

BACKGROUND

In the semiconductor industry, devices are fabricated by a number of manufacturing processes producing structures of an ever-decreasing size. Some manufacturing processes such as plasma etch and plasma clean processes expose a substrate to a high-speed stream of plasma to etch or clean the substrate. The plasma may be highly corrosive, and may corrode processing chambers and other surfaces that are exposed to the plasma.

Lids and nozzles are two important etch chamber components in conductor and dielectric etch. Typically lids and nozzles are made out of bulk ceramics. However, with a continuous decrease in device node, stringent defect requirements are dictated. Some of these newer applications use high operating temperatures (e.g., around 300° C. or above). Many bulk ceramics may crack due to thermal shock when used in such high temperature applications. Also, plasma resistant bulk ceramics are typically quite expensive.

Al₂O₃ may be used for lids and nozzles due to high thermal conductivity and flexural strength of Al₂O₃. However, under Fluorine chemistry, exposed Al₂O₃ forms AlF particles as well as Al metal contamination on processed wafers. Recent efforts have been made to coat the plasma facing side of the lid and nozzle with a thick protective coating. Thick-film coatings such as a plasma spray coating have been explored to reduce on-wafer metal contamination. However, vacuum sealing of the plasma spray coating has been a concern because in some instances the plasma spray coating does not maintain a vacuum due to inherent pores and cracks. Additionally, the plasma spray coating has a long lead time and typically is preceded by special surface preparation, which ultimately increases the cost. Also, refurbishing the coating can be a challenge due to surface preparation and cost.

The thin-film coating technique known as physical vapor deposition (PVD) has been considered for coating lids and nozzles. However, the PVD coating process is very slow (affects the ultimate cost of coating) and therefore may not generate coatings that are thick enough to meet the lifetime requirement of a component (especially for a non-consumable part like lid & nozzle). Additionally, PVD coatings typically have high residual stress, which in some instances will reduce the component lifetime due to coating cracking and peeling.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings in which like references indicate similar elements. It should be noted that different references to “an” or “one” embodiment in this disclosure are not necessarily to the same embodiment, and such references mean at least one.

FIG. 1 depicts a sectional view of one embodiment of a processing chamber.

FIG. 2A depicts a deposition mechanism applicable to a variety of deposition techniques utilizing energetic particles such as ion assisted deposition (IAD).

FIG. 2B depicts a schematic of an IAD deposition apparatus.

FIGS. 3-4 illustrate cross sectional side views of articles (e.g., lids and/or nozzles) covered by one or more thin film protective layers.

FIG. 5A illustrates a perspective view of a chamber lid having a rare earth oxide plasma resistant layer, in accordance with one embodiment.

FIG. 5B illustrates a cross-sectional side view of a chamber lid having a rare earth oxide plasma resistant layer, in accordance with one embodiment.

FIG. 5C illustrates a perspective view of a chamber nozzle having a rare earth oxide plasma resistant layer, in accordance with one embodiment.

FIG. 6 illustrates one embodiment of a process for forming one or more protective layers over a lid or nozzle.

FIG. 7 shows erosion rates of various materials exposed to dielectric etch CF₄ chemistry, including erosion rates of multiple different IAD coatings generated in accordance with embodiments described herein.

FIGS. 8 and 9 illustrate erosion rates under CH4-Cl2 and CHF3-NF3-Cl2 chemistries respectively for thin film protective layers formed in accordance with embodiments of the present invention.

FIGS. 10-11 illustrate roughness profiles under CH4-Cl2 and CHF3-NF3-Cl2 chemistries respectively for thin film protective layers formed in accordance with embodiments of the present invention.

FIG. 12 shows erosion rates of various materials exposed to a CF₄—CHF₃ trench chemistry at low bias.

DETAILED DESCRIPTION OF EMBODIMENTS

Embodiments of the present invention provide an article such as a lid and/or nozzle for an etch reactor having a thin film protective layer on one or more plasma facing surfaces of the article. The protective layer may have a thickness up to approximately 300 μm, and may provide plasma corrosion resistance for protection of the article. The protective layer may be formed on the article using ion assisted deposition (IAD) (e.g., using electron beam IAD (EB-IAD)). The thin film protective layer may be Y₃Al₅O₁₂, Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, Gd₃Al₅O₁₂, a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, or another rare-earth oxide. The improved erosion resistance provided by the thin film protective layer may improve the service life of the article, while reducing maintenance and manufacturing cost. Additionally, the IAD coating can be applied thick enough to provide a longer life time for the lid and/or nozzle, and may have a good hermetic sealing to maintain a vacuum. IAD coatings can be applied and later refurbished at low cost.

FIG. 1 is a sectional view of a semiconductor processing chamber 100 having one or more chamber components that are coated with a thin film protective layer in accordance with embodiments of the present invention. The processing chamber 100 may be used for processes in which a corrosive plasma environment is provided. For example, the processing chamber 100 may be a chamber for a plasma etch reactor (also known as a plasma etcher), a plasma cleaner, and so forth. Examples of chamber components that may include a thin film protective layer include a substrate support assembly 148, an electrostatic chuck (ESC) 150, a ring (e.g., a process kit ring or single ring), a chamber wall, a base, a gas distribution plate, a showerhead, a liner, a liner kit, a shield, a plasma screen, a flow equalizer, a cooling base, a chamber viewport, a chamber lid 104, a nozzle, and so on. In one particular embodiment, the protective layer is applied over a chamber lid 104 and/or a chamber nozzle 132.

The thin film protective layer, which is described in greater detail below is a rare earth oxide layer deposited by ion assisted deposition (IAD). The thin film protective layer may include Y₂O₃ and Y₂O₃ based ceramics, Y₃Al₅O₁₂ (YAG), Y₄Al₂O₉ (YAM), Er₂O₃ and Er₂O₃ based ceramics, Gd₂O₃ and Gd₂O₃ based ceramics, Er₃Al₅O₁₂ (EAG), Gd₃Al₅O₁₂ (GAG), Nd₂O₃ and Nd₂O₃ based ceramics, YAlO₃ (YAP), Er₄Al₂O₉ (EAM), ErAlO₃ (EAP), Gd₄Al₂O₉ (GdAM), GdAlO₃ (GdAP), Nd₃Al₅O₁₂ (NdAG), Nd₄Al₂O₉ (NdAM), NdAlO₃ (NdAP), and/or a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂. The thin film protective layer may also include YF₃, Er—Y compositions (e.g., Er 80 wt % and Y 20 wt %), Er—Al—Y compositions (e.g., Er 70 wt %, Al 10 wt %, and Y 20 wt %), Er—Y—Zr compositions (e.g., Er 70 wt %, Y 20 wt % and Zr-10 wt %), or Er—Al compositions (e.g., Er 80 wt % and Al 20 wt %).

The thin film protective layer may also be based on a solid solution formed by any of the aforementioned ceramics. With reference to the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, in one embodiment, the ceramic compound includes 62.93 molar ratio (mol %) Y₂O₃, 23.23 mol % ZrO₂ and 13.94 mol % Al₂O₃. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 50-75 mol %, ZrO₂ in a range of 10-30 mol % and Al₂O₃ in a range of 10-30 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 40-100 mol %, ZrO₂ in a range of 0-60 mol % and Al₂O₃ in a range of 0-10 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 40-60 mol %, ZrO₂ in a range of 30-50 mol % and Al₂O₃ in a range of 10-20 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 40-50 mol %, ZrO₂ in a range of 20-40 mol % and Al₂O₃ in a range of 20-40 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 70-90 mol %, ZrO₂ in a range of 0-20 mol % and Al₂O₃ in a range of 10-20 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 60-80 mol %, ZrO₂ in a range of 0-10 mol % and Al₂O₃ in a range of 20-40 mol %. In another embodiment, the ceramic compound can include Y₂O₃ in a range of 40-60 mol %, ZrO₂ in a range of 0-20 mol % and Al₂O₃ in a range of 30-40 mol %. In other embodiments, other distributions may also be used for the ceramic compound.

In one embodiment, an alternative ceramic compound that includes a combination of Y₂O₃, ZrO₂, Er₂O₃, Gd₂O₃ and SiO₂ is used for the protective layer. In one embodiment, the alternative ceramic compound can include Y₂O₃ in a range of 40-45 mol %, ZrO₂ in a range of 0-10 mol %, Er2O3 in a range of 35-40 mol %, Gd2O3 in a range of 5-10 mol % and SiO2 in a range of 5-15 mol %. In a first example, the alternative ceramic compound includes 40 mol % Y₂O₃, 5 mol % ZrO₂, 35 mol % Er₂O₃, 5 mol % Gd₂O₃ and 15 mol % SiO₂. In a second example, the alternative ceramic compound includes 45 mol % Y₂O₃, 5 mol % ZrO₂, 35 mol % Er₂O₃, 10 mol % Gd₂O₃ and 5 mol % SiO₂. In a third example, the alternative ceramic compound includes 40 mol % Y₂O₃, 5 mol % ZrO₂, 40 mol % Er₂O₃, 7 mol % Gd₂O₃ and 8 mol % SiO₂.

Any of the aforementioned thin film protective layers may include trace amounts of other materials such as ZrO₂, Al₂O₃, SiO₂, B₂O₃, Er₂O₃, Nd₂O₃, Nb₂O₅, CeO₂, Sm₂O₃, Yb₂O₃, or other oxides.

The thin film protective layer may be an IAD coating applied over different ceramics including oxide based ceramics, Nitride based ceramics and Carbide based ceramics. Examples of oxide based ceramics include SiO₂ (quartz), Al₂O₃, Y₂O₃, and so on. Examples of Carbide based ceramics include SiC, Si—SiC, and so on. Examples of Nitride based ceramics include AN, SiN, and so on. IAD coating target material can be calcined powders, preformed lumps (e.g., formed by green body pressing, hot pressing, and so on), a sintered body (e.g., having 50-100% density), or a machined body (e.g., can be ceramic, metal, or a metal alloy).

As illustrated, the lid 130 and nozzle 132 each have a thin film protective layer 133, 134, in accordance with one embodiment. However, it should be understood that any of the other chamber components, such as those listed above, may also include a thin film protective layer.

In one embodiment, the processing chamber 100 includes a chamber body 102 and a lid 130 that enclose an interior volume 106. The lid 130 may have a hole in its center, and a nozzle 132 may be inserted into the hole. The chamber body 102 may be fabricated from aluminum, stainless steel or other suitable material. The chamber body 102 generally includes sidewalls 108 and a bottom 110. Any of the lid 130, nozzle 132, sidewalls 108 and/or bottom 110 may include a thin film protective layer.

An outer liner 116 may be disposed adjacent the sidewalls 108 to protect the chamber body 102. The outer liner 116 may be fabricated and/or coated with a thin film protective layer. In one embodiment, the outer liner 116 is fabricated from aluminum oxide.

An exhaust port 126 may be defined in the chamber body 102, and may couple the interior volume 106 to a pump system 128. The pump system 128 may include one or more pumps and throttle valves utilized to evacuate and regulate the pressure of the interior volume 106 of the processing chamber 100.

The lid 130 may be supported on the sidewall 108 of the chamber body 102. The lid 130 may be opened to allow access to the interior volume 106 of the processing chamber 100, and may provide a seal for the processing chamber 100 while closed. A gas panel 158 may be coupled to the processing chamber 100 to provide process and/or cleaning gases to the interior volume 106 through the nozzle 132. The lid 130 may be a ceramic such as Al₂O₃, Y₂O₃, YAG, SiO₂, AN, SiN, SiC, Si—SiC, or a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂. The nozzle 132 may also be a ceramic, such as any of those ceramics mentioned for the lid. The lid 130 and/or nozzle 132 may be coated with a thin film protective layer 133, 134, respectively.

Examples of processing gases that may be used to process substrates in the processing chamber 100 include halogen-containing gases, such as C₂F₆, SF₆, SiCl₄, HBr, NF₃, CF₄, CHF₃, CH₂F₃, F, NF₃, Cl₂, CCl₄, BCl₃ and SiF₄, among others, and other gases such as O₂, or N₂O. Examples of carrier gases include N₂, He, Ar, and other gases inert to process gases (e.g., non-reactive gases). A substrate support assembly 148 is disposed in the interior volume 106 of the processing chamber 100 below the lid 130. The substrate support assembly 148 holds the substrate 144 during processing. A ring 146 (e.g., a single ring) may cover a portion of the electrostatic chuck 150, and may protect the covered portion from exposure to plasma during processing. The ring 146 may be silicon or quartz in one embodiment.

An inner liner 118 may be coated on the periphery of the substrate support assembly 148. The inner liner 118 may be a halogen-containing gas resist material such as those discussed with reference to the outer liner 116. In one embodiment, the inner liner 118 may be fabricated from the same materials of the outer liner 116. Additionally, the inner liner 118 may be coated with a thin film protective layer.

In one embodiment, the substrate support assembly 148 includes a mounting plate 162 supporting a pedestal 152, and an electrostatic chuck 150. The electrostatic chuck 150 further includes a thermally conductive base 164 and an electrostatic puck 166 bonded to the thermally conductive base by a bond 138, which may be a silicone bond in one embodiment. The mounting plate 162 is coupled to the bottom 110 of the chamber body 102 and includes passages for routing utilities (e.g., fluids, power lines, sensor leads, etc.) to the thermally conductive base 164 and the electrostatic puck 166.

The thermally conductive base 164 and/or electrostatic puck 166 may include one or more optional embedded heating elements 176, embedded thermal isolators 174 and/or conduits 168, 170 to control a lateral temperature profile of the support assembly 148. The conduits 168, 170 may be fluidly coupled to a fluid source 172 that circulates a temperature regulating fluid through the conduits 168, 170. The embedded isolator 174 may be disposed between the conduits 168, 170 in one embodiment. The heater 176 is regulated by a heater power source 178. The conduits 168, 170 and heater 176 may be utilized to control the temperature of the thermally conductive base 164, thereby heating and/or cooling the electrostatic puck 166 and a substrate (e.g., a wafer) 144 being processed. The temperature of the electrostatic puck 166 and the thermally conductive base 164 may be monitored using a plurality of temperature sensors 190, 192, which may be monitored using a controller 195.

The electrostatic puck 166 may further include multiple gas passages such as grooves, mesas and other surface features, that may be formed in an upper surface of the puck 166. The gas passages may be fluidly coupled to a source of a heat transfer (or backside) gas such as He via holes drilled in the puck 166. In operation, the backside gas may be provided at controlled pressure into the gas passages to enhance the heat transfer between the electrostatic puck 166 and the substrate 144.

The electrostatic puck 166 includes at least one clamping electrode 180 controlled by a chucking power source 182. The electrode 180 (or other electrode disposed in the puck 166 or base 164) may further be coupled to one or more RF power sources 184, 186 through a matching circuit 188 for maintaining a plasma formed from process and/or other gases within the processing chamber 100. The sources 184, 186 are generally capable of producing RF signal having a frequency from about 50 kHz to about 3 GHz and a power of up to about 10,000 Watts.

FIG. 2A depicts a deposition mechanism applicable to a variety of deposition techniques utilizing energetic particles such as ion assisted deposition (IAD). Exemplary IAD methods include deposition processes which incorporate ion bombardment, such as evaporation (e.g., activated reactive evaporation (ARE)) and sputtering in the presence of ion bombardment to form plasma resistant coatings as described herein. One particular type of IAD performed in embodiments is electron beam IAD (EB-IAD). Any of the IAD methods may be performed in the presence of a reactive gas species, such as O₂, N₂, halogens, etc. Such reactive species may burn off surface organic contaminants prior to and/or during deposition. Additionally, the IAD deposition process for ceramic target deposition vs. the metal target deposition can be controlled by partial pressure of O₂ ions in embodiments. For example a Y₂O₃ coating can be made by evaporation of a Y metal and bleeding of oxygen ions to form oxides the Yttrium material on the surface of the component. Alternatively, a ceramic target can be used with no oxygen or reduced oxygen.

As shown, the thin film protective layer 215 is formed on an article 210 or on multiple articles 210A, 210B by an accumulation of deposition materials 202 in the presence of energetic particles 203 such as ions. The deposition materials 202 may include atoms, ions, radicals, and so on. The energetic particles 203 may impinge and compact the thin film protective layer 215 as it is formed.

In one embodiment, EB IAD is utilized to form the thin film protective layer 215. FIG. 2B depicts a schematic of an IAD deposition apparatus. As shown, a material source 250 provides a flux of deposition materials 202 while an energetic particle source 255 provides a flux of the energetic particles 203, both of which impinge upon the article 210, 210A, 210B throughout the IAD process. The energetic particle source 255 may be an Oxygen or other ion source. The energetic particle source 255 may also provide other types of energetic particles such as inert radicals, neutron atoms, and nano-sized particles which come from particle generation sources (e.g., from plasma, reactive gases or from the material source that provide the deposition materials).

The material source (e.g., a target body) 250 used to provide the deposition materials 202 may be a bulk sintered ceramic corresponding to the same ceramic that the thin film protective layer 215 is to be composed of. For example, the material source may be a bulk sintered ceramic compound body, or bulk sintered YAG, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, or Gd₃Al₅O₁₂, or other mentioned ceramics. Other target materials may also be used, such as powders, calcined powders, preformed material (e.g., formed by green body pressing or hot pressing), or a machined body (e.g., fused material). All of the different types of material sources 250 are melted into molten material sources during deposition. However, different types of starting material take different amounts of time to melt. Fused materials and/or machined bodies may melt the quickest. Preformed material melts slower than fused materials, calcined powders melt slower than preformed materials, and standard powders melt more slowly than calcined powders.

IAD may utilize one or more plasmas or beams (e.g., electron beams) to provide the material and energetic ion sources. Reactive species may also be provided during deposition of the plasma resistant coating. In one embodiment, the energetic particles 203 include at least one of non-reactive species (e.g., Ar) or reactive species (e.g., O). In further embodiments, reactive species such as CO and halogens (Cl, F, Br, etc.) may also be introduced during the formation of a plasma resistant coating to further increase the tendency to selectively remove deposited material most weakly bonded to the thin film protective layer 215.

With IAD processes, the energetic particles 203 may be controlled by the energetic ion (or other particle) source 255 independently of other deposition parameters. According to the energy (e.g., velocity), density and incident angle of the energetic ion flux, composition, structure, crystalline orientation and grain size of the thin film protective layer may be manipulated.

Additional parameters that may be adjusted are a temperature of the article during deposition as well as the duration of the deposition. In one embodiment, an IAD deposition chamber (and the chamber lid or nozzle therein) is heated to a starting temperature of 160° C. or higher prior to deposition. In one embodiment, the starting temperature is 160° C. to 500° C. In one embodiment, the starting temperature is 200° C. to 270° C. The temperature of the chamber and of the lid or nozzle may then be maintained at the starting temperature during deposition. In one embodiment, the IAD chamber includes heat lamps which perform the heating. In an alternative embodiment, the IAD chamber and lid or nozzle are not heated. If the chamber is not heated, it will naturally increase in temperature to about 160° C. as a result of the IAD process. A higher temperature during deposition may increase a density of the protective layer but may also increase a mechanical stress of the protective layer. Active cooling can be added to the chamber to maintain a low temperature during coating. The low temperature may be maintained at any temperature at or below 160° C. down to 0° C. in one embodiment.

Additional parameters that may be adjusted are working distance 270 and angle of incidence 272. The working distance 270 is the distance between the material source 250 and the article 210A, 210B. In one embodiment, the working distance is 0.2 to 2.0 meters, with a working distance of 1.0 meters in one particular embodiment. Decreasing the working distance increases a deposition rate and increases an effectiveness of the ion energy. However, decreasing the working distance below a particular point may reduce a uniformity of the protective layer. The angle of incidence is an angle at which the deposition materials 202 strike the articles 210A, 210B. In one embodiment the angle of incidence is 10-90 degrees, with an angle of incidence of about 30 degrees in one particular embodiment.

IAD coatings can be applied over a wide range of surface conditions with roughness from about 0.5 micro-inches (μin) to about 180 μin. However, smoother surface facilitates uniform coating coverage. The coating thickness can be up to about 300 microns (μm). In production, coating thickness on components can be assessed by purposely adding a rare earth oxide based colored agent such Nd₂O₃, Sm₂O₃, Er₂O₃, etc. at the bottom of a coating layer stack. The thickness can also be accurately measured using ellipsometry.

IAD coatings can be amorphous or crystalline depending on the rare-earth oxide composite used to create the coating. For example EAG and YAG are amorphous coatings whereas Er₂O₃ and the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ are typically crystalline. Amorphous coatings are more conformal and reduce lattice mismatch induced epitaxial cracks whereas crystalline coatings are more erosion resistant.

Coating architecture can be a bi-layer or a multi-layer structure. In a bilayer architecture, an amorphous layer can be deposited as a buffer layer to minimize epitaxial cracks followed by a crystalline layer on the top which might be erosion resistant. In a multi-layer design, layer materials may be used to cause a smooth thermal gradient from the substrate to the top layer.

Co-deposition of multiple targets using multiple electron beam (e-beam) guns can be achieved to create thicker coatings as well as layered architectures. For example, two targets having the same material type may be used at the same time. Each target may be bombarded by a different electron beam gun. This may increase a deposition rate and a thickness of the protective layer. In another example, two targets may be different ceramic materials. A first electron beam gun may bombard a first target to deposit a first protective layer, and a second electron beam gun may subsequently bombard the second target to form a second protective layer having a different material composition than the first protective layer.

Post coating heat treatment can be used to achieve improved coating properties. For example, it can be used to convert an amorphous coating to a crystalline coating with higher erosion resistance. Another example is to improve the coating to substrate bonding strength by formation of a reaction zone or transition layer.

In one embodiment, multiple lids and/or nozzles are processed in parallel in an IAD chamber. For example, up to five lids and/or nozzles may be processed in parallel in one embodiment. Each lid or nozzle may be supported by a different fixture. Alternatively, a single fixture may be configured to hold multiple lids and/or nozzles. The fixtures may move the supported lids and/or nozzles during deposition.

In one embodiment, a fixture to hold a lid and/or nozzle can be designed out of metal components such as cold rolled steel or ceramics such as Al₂O₃, Y₂O₃, etc. The fixture may be used to support the lid or nozzle above or below the material source and electron beam gun. The fixture can have a chucking ability to chuck the lid and/or nozzle for safer and easier handling as well as during coating. Also, the fixture can have a feature to orient or align the lids and nozzles. In one embodiment, the fixture can be repositioned and/or rotated about one or more axes to change an orientation of the supported lid or nozzle to the source material. The fixture may also be repositioned to change a working distance and/or angle of incidence before and/or during deposition. The fixture can have cooling or heating channels to control the lid and nozzle temperature during coating. The ability or reposition and rotate the lid or nozzle may enable maximum coating coverage of 3D surfaces such as holes since IAD is a line of sight process.

FIGS. 3-4 illustrate cross sectional side views of articles (e.g., lids and/or nozzles) covered by one or more thin film protective layers. A lid for a plasma etch reactor used for conductor etch processes may be a sintered ceramic such as Al₂O₃ since Al₂O₃ has a high flexural strength and high thermal conductivity. However, Al₂O₃ exposed to Fluorine chemistries forms AlF particles as well as aluminum metal contamination on wafers. Other materials may also be used for the lid and/or nozzle.

Referring to FIG. 3, a body 305 of the article 300 includes a thin film stack 306 having a first thin film protective layer 308 and a second thin film protective layer 310. Alternatively, the article 300 may include only a single thin film protective layer 308 on the body 305. In one embodiment, the thin film protective layers 308, 310 have a thickness of up to about 300 μm. In a further embodiment, the thin film protective layers have a thickness of below about 20 microns, and a thickness between about 0.5 microns to about 7 microns in one particular embodiment. A total thickness of the thin film protective layer stack in one embodiment is 300 μm or less.

The thin film protective layers 308, 310 are deposited ceramic layers that may be formed on the body 305 of the article 300 using an electron beam ion assisted deposition (EB-IAD) process. The EB-IAD deposited thin film protective layers 308, 310 may have a relatively low film stress (e.g., as compared to a film stress caused by plasma spraying or sputtering). The relatively low film stress may cause the lower surface of the body 305 to be very flat, with a curvature of less than about 50 microns over the entire body for a body with a 12 inch diameter. The IAD deposited thin film protective layers 308, 310 may additionally have a porosity that is less than 1%, and less than about 0.1% in some embodiments. This low porosity may enable the lid to provide an effective vacuum seal during processing. Therefore, the IAD deposited protective layer is a dense structure, which can have performance benefits for application on a chamber lid or nozzle. Additionally, the IAD deposited protective layer may have a low crack density and a high adhesion to the body 305. Additionally, the IAD deposited protective layers 308, 310 may be deposited without first roughening the upper surface of the body 305 or performing other time consuming surface preparation steps.

Examples of ceramics that may be used to form the thin film protective layer 208 include Y₃Al₅O₁₂, Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, Gd₃Al₅O₁₂, a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ (Y₂O₃—ZrO₂ solid solution), or any of the other ceramic materials previously identified. Other Er based and/or Gd based plasma resistant rare earth oxides may also be used to form the thin film protective layers 308, 310. In one embodiment, the same ceramic material is not used for two adjacent thin film protective layers. However, in another embodiment adjacent layers may be composed of the same ceramic.

Lids and nozzles having IAD thin film protective layers may be used in applications that apply a wide range of temperatures. For example, lids and nozzles with IAD thin film protective layers may be used in processes having temperatures at 0° C. to temperatures at 1000° C. The lids and nozzles may be used at high temperatures (e.g., at or above 300° C.) without cracking caused by thermal shock.

TABLE 1 Material properties for IAD deposited YAG, Er₂O₃, EAG and ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂. 92% Ceramic Property Al₂O₃ Cmpd. YAG Er₂O₃ EAG Y₂O₃ YZ20 YF₃ Crystal C A A C A C C A Structure Breakdown 363 427 1223 527 900 1032 423    522     Voltage (V) (5 μm) (5 μm) (5 μm) Volume >0.01E16 4.1E16 11.3E16 — — — — — Resistivity (Ω · cm) Dielectric 9.2 9.83 +/− 9.76 +/− 9.67  9.54  — — — Constant 0.04 0.01 Loss    5E−4   4E−4   4E−4   4E−4  4E−4 — — — Tangent Thermal 18 19.9 20.1 19.4   19.2   — — — Conductivity (W/m-K) Roughness 8-16 Same Same Same Same Same Same Same (μin) Adhesion N/A >28 >32 — — — — — Over 92% Al₂O₃ (MPa) Hermicity   <1E−6 1.2E−9  4.4E−10 5.5E−9 9.5E−10 — 1.6E−7 2.6E−9 (leak rate) (cm³/s) Hardness 12.14 7.825 8.5 5.009 9.057 — 5.98 3.411 (GPa) Wear Rate 0.2 0.14 0.28 0.113 0.176 — — — (nm/RFhr)

Table 1 shows material properties for a substrate of 92% Al₂O₃ (alumina) and for various IAD thin film protective layers coating a substrate of 92% Al₂O₃. In the table “C” represents a crystalline structure and “A” represents an amorphous structure. As shown, the alumina substrate has a breakdown voltage of 363 Volts/mil (V/mil). In contrast, a 5 micron (μm) coating of the IAD deposited ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ has a breakdown voltage of 427 V (much more than the normalized value of 363 Volts/mil for alumina). A 5 μm coating of the IAD deposited YAG has a breakdown voltage of 1223 V. A 5 μm coating of the IAD deposited Er₂O₃ has a breakdown voltage of 527 V. A 5 μm coating of the IAD deposited EAG has a breakdown voltage of 900 V. A 5 μm coating of the IAD deposited Y₂O₃ has a breakdown voltage of 1032 V. A 5 μm coating of the IAD deposited YZ20 has a breakdown voltage of 423 V. A 5 μm coating of the IAD deposited YF₃ has a breakdown voltage of 522V.

A volume resistivity of the alumina is around 0.01×10¹⁶ (0.01E16) Ω·cm at room temperature. A volume resistivity of the ceramic compound thin film protective layer is about 4.1E16 Ω·cm at room temperature, and a volume resistivity of the YAG thin film protective layer is about 11.3E16 Ω·cm at room temperature.

A dielectric constant of the alumina is about 9.2, a dielectric constant of the ceramic compound thin film is about 9.83, a dielectric constant of the YAG thin film is about 9.76, a dielectric constant of the Er₂O₃ thin film is about 9.67, and a dielectric constant of the EAG thin film is about 9.54. A loss tangent of the alumina is about 5E-4, a loss tangent of the ceramic compound thin film is about 4E-4, a loss tangent of the YAG thin film is about 4E-4, a loss tangent of the Er₂O₃ thin film is about 4E-4, and a loss tangent of the EAG thin film is about 4E-4. A thermal conductivity of the alumina is about 18 W/m-K, a thermal conductivity of the ceramic compound thin film is about 19.9 W/m-K, a thermal conductivity of the YAG thin film is about 20.1 W/m-K, a thermal conductivity of the Er₂O₃ thin film is about 19.4 W/m-K, and a thermal conductivity of the EAG thin film is about 19.2 W/m-K.

The alumina substrate may have a starting roughness of approximately 8-16 micro-inches in one embodiment, and that starting roughness may be approximately unchanged in all of the thin film protective layers. The protective layer may be polished to reduce a surface roughness to 8 micro-inches or below after deposition. In one embodiment, the protective layer is polished to a surface roughness of 6-8 micro-inches.

Adhesion strength of the thin film protective layers to the alumina substrate may be above 28 mega pascals (MPa) for the ceramic compound thin film and above 32 MPa for the YAG thin film. Adhesion strength may be determined by measuring the amount of force used to separate the thin film protective layer from the substrate. Hermicity measures the sealing capacity that can be achieved using the thin film protective layer. As shown, a He leak rate of around 1E-6 cubic centimeters per second (cm³/s) can be achieved using alumina, a He leak rate of around 1.2E-9 can be achieved using the ceramic compound, a He leak rate of around 4.4E-10 can be achieved using YAG, a He leak rate of around 5.5E-9 can be achieved using Er₂O₃, a He leak rate of around 2.6E-9 can be achieved using YF3, a He leak rate of around 1.6E-7 can be achieved using YZ20, and a He leak rate of around 9.5E-10 can be achieved using EAG. Lower He leak rates indicate an improved seal. Each of the example thin film protective layers has a lower He leak rate than typical Al₂O₃.

Each of Y₃Al₅O₁₂, Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, Gd₃Al₅O₁₂, and the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ have a high hardness that may resist wear during plasma processing. As shown, alumina has a Vickers hardness (5 Kgf) of around 12.14 Giga pascals (GPa), the ceramic compound has a hardness of around 7.825 GPa, YAG has a hardness of around 8.5 GPa, Er₂O₃ has a hardness of around 5.009 GPa, YZ20 has a hardness of around 5.98 GPa, YF₃ has a hardness of around 3.411 GPa and EAG has a hardness of around 9.057 GPa, A measured wear rate of alumina is around 0.2 nanometers per radio frequency hour (nm/RFhr), a wear rate of the ceramic compound is about 0.14 nm/RFhr, a wear rate of Er₂O₃ is about 0.113 nm/RFhr, and a wear rate of EAG is about 0.176 nm/RFhr.

Note that the Y₃Al₅O₁₂, Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, Gd₃Al₅O₁₂, and the ceramic compound may be modified such that the material properties and characteristics identified above may vary by up to 30% in some embodiments. Accordingly, the described values for these material properties should be understood as example achievable values. The ceramic thin film protective layers described herein should not be interpreted as being limited to the provided values.

FIG. 4 illustrates a cross sectional side view of another embodiment of an article 400 having a thin film protective layer stack 406 deposited over a body 405 of the article 400. Article 400 is similar to article 400, except that thin film protective layer stack 406 has four thin film protective layers 408, 410, 415, 418.

The thin film protective layer stacks (such as those illustrated) may have any number of thin film protective layers. The thin film protective layers in a stack may all have the same thickness, or they may have varying thicknesses. Each of the thin film protective layers may have a thickness of less than approximately 20 microns in some embodiments. In one example, a first layer 408 may have a thickness of 10 microns, and a second layer 410 may have a thickness of 10 microns. In another example, first layer 408 may be a YAG layer having a thickness of 5 microns, second layer 410 may be a compound ceramic layer having a thickness of 5 microns, third layer 415 may be a YAG layer having a thickness of 5 microns, and fourth layer 418 may be a compound ceramic layer having a thickness of 5 microns.

The selection of the number of ceramic layers and the composition of the ceramic layers to use may be based on a desired application and/or a type of article being coated. EAG and YAG thin film protective layers formed by IAD typically have an amorphous structure. In contrast, the IAD deposited compound ceramic and Er₂O₃ layers typically have a crystalline or nano-crystalline structure. Crystalline and nano-crystalline ceramic layers may generally be more erosion resistant than amorphous ceramic layers. However, in some instances thin film ceramic layers having a crystalline structure or nano-crystalline structure may experience occasional vertical cracks (cracks that run approximately in the direction of the film thickness and approximately perpendicular to the coated surface). Such vertical cracks may be caused by lattice mismatch and may be points of attack for plasma chemistries. Each time the article is heated and cooled, the mismatch in coefficients of thermal expansion between the thin film protective layer and the substrate that it coats can cause stress on the thin film protective layer. Such stress may be concentrated at the vertical cracks. This may cause the thin film protective layer to eventually peel away from the substrate that it coats. In contrast, if there are not vertical cracks, then the stress is approximately evenly distributed across the thin film. Accordingly, in one embodiment a first layer 408 in the thin film protective layer stack 406 is an amorphous ceramic such as YAG or EAG, and the second layer 410 in the thin film protective layer stack 406 is a crystalline or nano-crystalline ceramic such as the ceramic compound or Er₂O₃. In such an embodiment, the second layer 410 may provide greater plasma resistance as compared to the first layer 408. By forming the second layer 410 over the first layer 408 rather than directly over the body 405, the first layer 408 acts as a buffer to minimize lattice mismatch on the subsequent layer. Thus, a lifetime of the second layer 410 may be increased.

In another example, each of the body, Y₃Al₅O₁₂ (YAG), Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₅O₁₂, Gd₃Al₅O₁₂, the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, and other ceramics may have a different coefficient of thermal expansion. The greater the mismatch in the coefficient of thermal expansion between two adjacent materials, the greater the likelihood that one of those materials will eventually crack, peel away, or otherwise lose its bond to the other material. The protective layer stacks 306, 406 may be formed in such a way to minimize mismatch of the coefficient of thermal expansion between adjacent layers (or between a layer and a body 305, 405). For example, body 405 may be alumina, and EAG may have a coefficient of thermal expansion that is closest to that of alumina, followed by the coefficient of thermal expansion for YAG, followed by the coefficient of thermal expansion for the compound ceramic. Accordingly, first layer 408 may be EAG, second layer 410 may be YAG, and third layer 415 may be the compound ceramic in one embodiment.

In another example, the layers in the protective layer stack 406 may be alternating layers of two different ceramics. For example, first layer 408 and third layer 415 may be YAG, and second layer 410 and fourth layer 418 may be the compound ceramic. Such alternating layers may provide advantages similar to those set forth above in cases where one material used in the alternating layers is amorphous and the other material used in the alternating layers is crystalline or nano-crystalline.

In some embodiments, one of more of the layers in the thin film protective layer stacks 306, 406 are transition layers formed using a heat treatment. If the body 305, 405 is a ceramic body, then a high temperature heat treatment may be performed to promote interdiffusion between a thin film protective layer and the body. Additionally, the heat treatment may be performed to promote interdiffusion between adjacent thin film protective layers or between a thick protective layer and a thin film protective layer. Notably, the transition layer may be a non-porous layer. The transition layer may act as a diffusion bond between two ceramics, and may provide improved adhesion between the adjacent ceramics. This may help prevent a protective layer from cracking, peeling off, or stripping off during plasma processing.

The thermal treatment may be a heat treatment at up to about 1400-1600 degrees C. for a duration of up to about 24 hours (e.g., 3-6 hours in one embodiment). This may create an inter-diffusion layer between a first thin film protective layer and one or more of an adjacent ceramic body or second thin film protective layer. If the ceramic body is Al₂O₃, and the protective layer is composed of a compound ceramic Y₄Al₂O₉ (YAM) and a solid solution Y₂-xZr_(x)O₃ (Y₂O₃—ZrO₂ solid solution), then a Y₃Al₅O₁₂ (YAG) interface layer will be formed. Similarly, a heat treatment will cause a transition layer of EAG to form between Er₂O₃ and Al₂O₃. A heat treatment will also cause a transition layer of YAG to form between Y₂O₃ and Al₂O₃. A heat treatment may also cause GAG to form between Gd₂O₃ and Al₂O₃. A heat treatment of yttria stabilized zirconia (YSZ) over Al₂O₃ can form a transition layer of the compound ceramic of Y₄Al₂O₉ (YAM) and a solid solution Y₂-xZr_(x)O₃. Other transition layers may be formed between other adjacent ceramics.

In one embodiment, a coloring agent is added during the deposition of the first protective layer 308, 408. Accordingly, when the second protective layer 310, 410 wears away, an operator may have a visual queue that it is time to refurbish or exchange the lid or nozzle.

FIG. 5A illustrates a perspective view of a chamber lid 505 having a thin film rare earth oxide plasma resistant layer 510, in accordance with one embodiment. FIG. 5B illustrates a cross-sectional side view of a chamber lid 505 having a thin film rare earth oxide plasma resistant layer 510, in accordance with one embodiment. The chamber lid 505 includes a hole 520, which may be at a center of the lid or elsewhere on the lid. The lid 505 may also have a lip 515 that will be in contact with walls of a chamber while the lid is closed. In one embodiment, the protective layer 510 does not cover the lip 515. To ensure that the protective layer does not cover the lip 515, a hard or soft mask may be used that covers the lip 515 during deposition. The mask may then be removed after deposition. Alternatively, the protective layer 510 may coat the entire surface of the lid. Accordingly, the protective layer 510 may rest on side walls of a chamber during processing. Additionally, the outside walls of the lid 505 may also be coated with the plasma resistant layer 555 in some embodiments.

As shown in FIG. 5B, the protective layer 510 may have a sidewall portion 530 that coats an interior of the hole 520. The sidewall portion 530 of the protective layer 510 may by thicker near a surface of the lid 505, and may gradually become thinner deeper into the hole 520. The sidewall portion 530 may not coat an entirety of the sidewalls of the hole 520 in such embodiments.

FIG. 5C illustrates a perspective view of a chamber nozzle 550 having a rare earth oxide plasma resistant layer 555, in accordance with one embodiment. As shown, the rare earth oxide plasma resistant layer 555 may coat an end and sidewalls of the chamber nozzle 550. The chamber nozzle 550 may be inserted into the lid 505. In one embodiment, the nozzle 550 includes a lip 565 that rests on the lid 505. The lip 565 may not be coated with the plasma resistant layer 555. Alternatively, the lip 565 may be coated with the plasma resistant layer 555.

FIG. 6 illustrates one embodiment of a process 600 for forming a thin film protective layer over a body of a chamber lid or chamber nozzle. At block 605 of process 600, chamber lid or nozzle is provided. The lid or nozzle may have a bulk sintered ceramic body. The bulk sintered ceramic body may be Al₂O₃, Y₂O₃, SiO₂, or the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂.

At block 620, an ion assisted deposition (IAD) process is performed to deposit a rare earth oxide protective layer onto at least one surface of the lid or nozzle. In one embodiment, an electron beam ion assisted deposition process (EB-IAD) is performed. The IAD process may be performed by melting a material that is to be deposited and bombarding the material with ions.

The thin film protective layer may be Y₃Al₆O₁₂, Y₄Al₂O₉, Er₂O₃, Gd₂O₃, Er₃Al₆O₁₂, Gd₃Al₆O₁₂, or the ceramic compound of Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, or other rare earth oxides described herein. A deposition rate for the thin film protective layer may be about 0.02-20 Angstroms per second (A/s) in one embodiment, and may be varied by tuning deposition parameters. In one embodiment, a deposition rate of 0.25-1 A/s is initially used to achieve a conforming well adhering coating on the substrate. A deposition rate of 2-10 A/s may then be used for depositing a remainder of a thin film protective layer to achieve a thicker coating in a shorter time. The thin film protective layers may be very conforming, may be uniform in thickness, and may have a good adhesion to the body/substrate that they are deposited on.

In one embodiment, the material includes a coloring agent that will cause the deposited protective layer to have a particular color. Examples of coloring agents that may be used include Nd₂O₃, Sm₂O₃ and Er₂O₃. Other coloring agents may also be used.

At block 625, a determination is made regarding whether to deposit any additional thin film protective layers. If an additional thin film protective layer is to be deposited, the process continues to block 630. At block 630, another thin film protective layer is formed over the first thin film protective layer. The other thin film protective layer may be composed of a ceramic that is different than a ceramic of the first thin film protective layer. Alternatively, the other thin film protective layer may be composed of the same ceramic or ceramics that were used to form the first protective layer.

In one embodiment, the other thin film protective layer does not include any coloring agent. Accordingly, the subsequent protective layers may have a different color than the bottom protective layer, even if they are composed of the almost the same ceramic materials. This causes the lid or nozzle to change color when the protective layer stack is eroded down to the bottom protective layer. The change in color may signal to an operator that it is time to change the lid or nozzle of a processing chamber.

After a subsequent protective layer is deposited, the method returns to block 625. If at block 625 no additional thin film protective layers are to be applied, the process proceeds to block 635. At block 635, a surface of the protective layer is polished. The surface may be polished using chemical mechanical polishing (CMP) or other polishing procedures. In one embodiment, the surface of the top protective layer is polished to a surface roughness of below 8 micro-inches. In another embodiment, the surface of the top protective layer is polished to a surface of below 6 micro-inches.

Process 600 may be performed on new lids and nozzles or on used lids and nozzles to refurbish the used lids and nozzles. In one embodiment, used lids and nozzles are polished before performing process 600. For example, previous protective layers may be removed by polishing before performing process 600.

With IAD processes, the energetic particles may be controlled by the energetic ion (or other particle) source independently of other deposition parameters. According to the energy (e.g., velocity), density and incident angle of the energetic ion flux, composition, structure, crystalline orientation and grain size of the thin film protective layer may be manipulated. Additional parameters that may be adjusted are a temperature of the article during deposition as well as the duration of the deposition. The ion energy may be roughly categorized into low energy ion assist and high energy ion assist. Low energy ion assist may include a voltage of about 230V and a current of about 5 A. High energy ion assist may include a voltage of about 270V and a current of about 7 A. The low and high energy for the ion assist is not limited to the values mentioned herein. The high and low level designation may additionally depend on the type of the ions used and/or the geometry of the chamber used to perform the IAD process. The ions are projected with a higher velocity with high energy ion assist than with low energy ion assist. Substrate (article) temperature during deposition may be roughly divided into low temperature (around 120-150° C. in one embodiment which is typical room temperature) and high temperature (around 270° C. in one embodiment). For high temperature IAD deposition processes, the lid or nozzle may be heated prior to and during deposition.

TABLE 2A Example Thin Film Protective Layers Formed Using IAD Thk. Dep. Rate Ion Temp. Vacuum Hardness Material (μm) (A/s) Assist (° C.) XRD (cm³/s) (GPa) 1^(st) Compound Ceramic 5 2 230 V, 270 C N/A 4.11  (sintered plug) 5 A 2^(nd) Compound Ceramic 6 1 for 2 μm 230 V, 270 C + A 5.0E−6 (sintered plug) 2 for 4 μm 5 A 3^(rd) Compound Ceramic 5 1 230 V, 270 C + A 6.3E−6 (sintered plug) 5 A 4^(th) Compound Ceramic 5 1 for 1 μm 270 V, 270 A 1.2E−9 7.825 (sintered plug) 2 for 4 μm 7 A 5^(th) Compound Ceramic 5 1 for 1 μm 270 V, 120- A 1.2E−9 (calcined powder) 2 for 4 μm 7 A 150 6^(th) Compound Ceramic 5 1 for 1 μm 270 V, 120- A 1.2E−9 7.812 (calcined powder) 4 for 4 μm 7 A 150

TABLE 2B Example Thin Film Protective Layers Formed Using IAD Thk. Dep. Rate Ion Temp. Vacuum Hardness Material (μm) (A/s) Assist (° C.) XRD (cm³/s) (GPa) 1^(st) YAG 5   2.5 230 V, 270 A 3.7E−7 5.7 (fused lump) 5 A 2^(nd) YAG (fused lump) 5 1 for 1 μm 270 V, 270 A  4.4E−10 8.5 2 for 4 μm 7 A Compound Ceramic/YAG 5 2 230 V, 270 C + A 3.7E−7 5 A 1^(st) Er₂O₃ (sintered lump) 5 2 230 V, 270 C   3E−6 5 A 2^(nd) Er₂O₃ (sintered lump) 5 1 for 1 μm 270 V, 270 C 5.5E−9 5.009 2 for 4 μm 7 A 1^(st) EAG 7.5 1 for 1 μm 270 V, 270 A  9.5E−10 8.485 (calcined powder) 2 for next 7 A 2^(nd) EAG (calcined power) 7.5 1 for 1 μm 270 V, 120- A 2.5E−9 9.057 2 for next 7 A 150 3^(rd) EAG (calcined 5 1 for 1 μm 270 V, A powder) 2 for 4 μm 7 A Y₂O₃ (fused lump) 5 1 for 1 μm 270 V, 270 C 2 for 4 μm 7 A YZ20 (Powder) 5 1 for 1 μm 270 V, 120- C 1.6E−7 5.98 2 for 4 μm 7 A 150 YF₃ 5 1 for 1 μm 270 V, 120- A 2.6E−9 3.411 2 for 4 μm 7 A 150

Tables 2A-2B show multiple example thin film protective layers formed using IAD with various deposition parameters. The experimental results identify an optimized coating process based on a multi-factorial design of experiments (DOE) that varies ion assisted energy, deposition rate and temperature to obtain a conforming, dense microstructure. The coatings are characterized in terms of material properties (microstructure and/or crystal phase) and mechanical properties (hardness and adhesion), as well as crack density and vacuum sealing capability. IAD coating process optimization can produce IAD coatings with high density thin-films (up to ˜300 μm in thickness) with low residual stress. The optimized parameters can be used for most rare earth oxide based coating materials.

Six different examples are shown for thin film protective layers formed from the ceramic compound of Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂. A first example compound ceramic thin film protective layer has a thickness of 5 microns, and was formed using IAD with a low energy ion assist and a sintered plug target, a deposition temperature of 270° C., and a deposition rate of 2 angstroms per seconds (A/s). X-ray diffraction showed that the first example compound ceramic thin film protective layer had a crystalline structure. The first example compound ceramic thin film protective layer also had a hardness of 4.11 GPa and visual inspection showed good conformance to the underlying substrate as well as some vertical cracks and some spikes.

A second example compound ceramic thin film protective layer has a thickness of 6 microns, and was formed using IAD with a low energy ion assist and a sintered plug target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for the first 2 microns and a deposition rate of 2 A/s for the subsequent 4 microns. X-ray diffraction showed that the second example compound ceramic thin film protective layer had a nano-crystalline structure (in which portions are crystalline and portions are amorphous). When used as a seal, the second example compound ceramic thin film protective layer was able to maintain a vacuum down to 5E-6 cubic centimeters per second (cm³/s). Visual inspection of the second example compound ceramic thin film protective layer showed good conformance and fewer vertical cracks than the first example compound ceramic thin film protective layer.

A third example compound ceramic thin film protective layer has a thickness of 5 microns, and was formed using IAD with a low energy ion assist and a sintered plug target, a deposition temperature of 270° C., and a deposition rate of 1 A/s. X-ray diffraction showed that the third example compound ceramic thin film protective layer had a nano-crystalline structure. When used as a seal, the third example compound ceramic thin film protective layer was able to maintain a vacuum down to 6.3E-6 cm³/s. Visual inspection of the third example compound ceramic thin film protective layer showed good conformance and fewer vertical cracks than the first example compound ceramic thin film protective layer.

A fourth example compound ceramic thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a sintered plug target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for the first micron and 2 A/s for the subsequent 4 microns. X-ray diffraction showed that the third example compound ceramic thin film protective layer had an approximately amorphous structure. When used as a seal, the third example compound ceramic thin film protective layer was able to maintain a vacuum down to 1.2E-9 cm³/s. Visual inspection of the fourth example compound ceramic thin film protective layer showed good conformance, a smooth surface and very few vertical cracks. Additionally, the fourth example compound ceramic thin film protective layer has a hardness of 7.825 GPa.

A fifth example compound thin film protective layer was formed using the same parameters as the fourth example compound thin film protective layer, but with a deposition temperature at room temperature (around 120-150° C.) and with a calcined powder target. The fifth example compound thin film protective layer showed similar properties to those of the fourth example compound thin film protective layer.

A sixth example compound ceramic thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a calcined powder target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for the first micron and 4 A/s for the subsequent 4 microns. X-ray diffraction showed that the third example compound ceramic thin film protective layer had an approximately amorphous structure. When used as a seal, the third example compound ceramic thin film protective layer was able to maintain a vacuum down to 1.2E-9 cm³/s. The fourth example compound ceramic thin film protective layer has a hardness of 7.812 GPa.

A first example YAG thin film protective layer has a thickness of 5 microns, and was formed using IAD with a low energy ion assist and a fused lump target, a deposition temperature of 270° C., and a deposition rate of 2.5 A/s. X-ray diffraction showed that the first YAG ceramic thin film protective layer had an amorphous structure. The first YAG thin film protective layer also had a hardness of 5.7 GPa and visual inspection showed good conformance, minimal cracking and a smooth surface.

A second example YAG thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a fused lump target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for a first micron and 2 A/s for the subsequent 4 microns. X-ray diffraction showed that the second YAG thin film protective layer had an amorphous structure. The second YAG thin film protective layer also had a hardness of 8.5 GPa and visual inspection showed good conformance, reduced cracking compared to the first YAG thin film and a smooth surface.

An example thin film protective layer stack with alternating compound ceramic and YAG layers has a thickness of 5 microns, and was formed using IAD with a low energy ion assist, a deposition temperature of 270° C., and a deposition rate of 2 A/s. X-ray diffraction showed that the alternating layers were amorphous (for the YAG layers) and crystalline or nano-crystalline (for the compound ceramic layers). Visual inspection showed reduced vertical cracks for the compound ceramic layers.

A first example Er₂O₃ thin film protective layer has a thickness of 5 microns, and was formed using IAD with a low energy ion assist and a sintered lump target, a deposition temperature of 270° C., and a deposition rate of 2 A/s. X-ray diffraction showed that the first Er₂O₃ ceramic thin film protective layer had a crystalline structure. Visual inspection showed good conformance and a vertical cracking.

A second example Er₂O₃ thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a sintered lump target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent 4 microns. X-ray diffraction showed that the second Er₂O₃ ceramic thin film protective layer had a crystalline structure. Visual inspection showed good conformance and a less vertical cracking compared to the first Er₂O₃ ceramic thin film protective layer.

A first example EAG thin film protective layer has a thickness of 7.5 microns, and was formed using IAD with a high energy ion assist and a calcined powder target, a deposition temperature of 270° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the first EAG ceramic thin film protective layer had an amorphous structure, and the layer had a hardness of 8.485 GPa. Visual inspection showed good conformance and minimal cracking.

A second example EAG thin film protective layer has a thickness of 7.5 microns, and was formed using IAD with a high energy ion assist and a calcined powder target, a deposition temperature of 120-150° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the second EAG ceramic thin film protective layer had an amorphous structure, and the layer had a hardness of 9.057 GPa. Visual inspection showed good conformance and a less cracking compared to the first EAG ceramic thin film protective layer.

A third example EAG thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a calcined powder target, and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the third EAG ceramic thin film protective layer had an amorphous structure.

An example Y₂O₃ thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a fused lump target, a temperature of 270° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the third EAG ceramic thin film protective layer had a crystalline structure.

An example YZ20 thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist and a powder target, a temperature of 120-150° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the YZ20 ceramic thin film protective layer had a crystalline structure. When used as a seal, the YZ20 ceramic thin film protective layer was able to maintain a vacuum down to 1.6E-7 cm³/s. The YZ20 ceramic thin film protective layer had a hardness of 5.98 GPa

An example YF₃ thin film protective layer has a thickness of 5 microns, and was formed using IAD with a high energy ion assist, a temperature of 120-150° C., and a deposition rate of 1 A/s for the first micron and a deposition rate of 2 A/s for the subsequent microns. X-ray diffraction showed that the YF₃ ceramic thin film protective layer had an amorphous structure. When used as a seal, the YF₃ ceramic thin film protective layer was able to maintain a vacuum down to 2.6E-9 cm³/s. The YF₃ ceramic thin film protective layer had a hardness of 3.411 GPa

TABLE 3 IAD Lid & Nozzle Optimized Coating Process Parameters Parameter Affects Optimization Range Voltage (V) Density & 188 150-270 Conformance Current (A) Density & 7 5-7 Conformance Temperature (° C.) Film Stress, 150 100-270 Crystalinity Deposition rate (A/s) Conformance 1 0.01-20   Angle of incidence Ability to coat 3D 30  0-90 (degrees) geometry Working distance (in.) Coating thickness, 50  10-300 deposition rate

Table 3 shows optimized IAD processing parameters for coating a chamber lid or nozzle, in accordance with one embodiment. Table 3 additionally shows processing parameter ranges that may be used in some embodiments to deposit thin film protective layers. In other embodiments, wider ranges of some of the processing values may be used. In one embodiment, an IAD process is performed using a voltage of 150-270 Volts (V), a current of 5-7 Amps (A), a temperature of 100-270° C., a deposition rate of 0.01-20 Angstroms per second (A/s), an angle of incidence of 0-90 degrees, and a working distance of 10-300 inches (in.). In another embodiment, an IAD process is performed using a voltage of 50-500V, a current of 1-50 A, a temperature of 20-500° C., a deposition rate of 0.01-20 A/s, a working distance of 10-300 inches, and an angle of incidence of 10-90 degrees.

The coating deposition rate can be controlled by adjusting an amount of heat that is applied by an electron beam. The ion assist energy may be used to densify the coating and to accelerate the deposition of material on the surface of the lid or nozzle. The ion assist energy can be modified by adjusting the voltage and/or the current of the ion source. The current and voltage can be adjusted to achieve high and low coating density, to manipulate the stress of the coating, and also to affect the crystallinity of the coating. The ion assist energy can be varied from 50-500 V and from 1-50 A. The deposition rate can be varied from 0.01 to 20 A/s.

In one embodiment, a high ion assist energy used with a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ forms an amorphous protective layer and a low ion assist energy used with the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ forms a crystalline protective layer. The ion assist energy can also be used to change a stoichiometry of the protective layer. For example, a metallic target can be used, and during deposition metallic material converts to a metal oxide by the incorporation of oxygen ions at the surface of the lid or nozzle. Also, using an oxygen gun the level of any metal oxide coating can be changed and optimized to achieve desired coating properties. For example most rare earth oxides lose oxygen inside a vacuum chamber. By bleeding more oxygen inside the chamber the oxygen deficiency of the oxide coating material can be compensated.

Coating temperature can be controlled by using heaters (e.g., heat lamps) and by controlling the deposition rate. A higher deposition rate will typically cause the temperature of the lid or nozzle to increase. The deposition temperature can be varied to control a film stress, crystallinity, and so on. Temperature can be varied from 20° C. to 500° C.

The working distance can be adjusted to modify uniformity, density and deposition rate. Working distance can be varied from 10-300 inches. The deposition angle can be varied by the location of the electron beam gun or electron beam hearth, or by changing a location of the lid or nozzle in relation to the electron beam gun or electron beam hearth. By optimizing the deposition angle, a uniform coating in three dimensional geometries can be achieved. Deposition angle can be varied from 0-90 degrees, and from 10-90 degrees in one embodiment.

In one embodiment, an IAD process is performed using a voltage of about 188 V in combination with other processing parameters having any of the associated processing parameter ranges. In one embodiment, an IAD process is performed using a current of about 7 A in combination with other processing parameters having any of the associated processing parameter ranges. In one embodiment, an IAD process is performed using temperature of about 150° C. in combination with other processing parameters having any of the associated processing parameter ranges. In one embodiment, an IAD process is performed using a deposition rate of 1 A/s in combination with other processing parameters having any of the associated processing parameter ranges. In a further embodiment, a deposition rate of 2 A/s is used until a deposited thin film reaches a thickness of 1 μm, after which a deposition rate of 1 A/s is used. In another embodiment, a deposition rate of 0.25-1 A/s is initially used to achieve a conforming well adhering coating on the substrate. A deposition rate of 2-10 A/s may then be used for depositing a remainder of a thin film protective layer to achieve a thicker coating in a shorter time.

In one embodiment, an IAD process is performed using an angle of incidence of about 30 degrees in combination with other processing parameters having any of the associated processing parameter ranges. In one embodiment, an IAD process is performed using a working distance of about 50 inches in combination with other processing parameters having any of the associated processing parameter ranges.

FIG. 7 shows erosion rates of various materials exposed to dielectric etch CF₄ chemistry, including erosion rates of multiple different IAD coatings generated in accordance with embodiments described herein. As shown, an erosion rate of 92% alumina is around 1.38 microns per radiofrequency hour (μm/Rfhr), an erosion rate of 99.8% alumina is around 1.21 μm/Rfhr, an erosion rate of IAD deposited YAG is around 0.28 μm/Rfhr, an erosion rate of IAD deposited EAG is about 0.24 μm/Rfhr, an erosion rate of IAD deposited Y2O3 is about 0.18 μm/Rfhr, an erosion rate of IAD deposited Er₂O₃ is about 0.18 μm/Rfhr, and an erosion rate of IAD deposited compound ceramic is about 0.18 μm/Rfhr. A radiofrequency hour is an hour of processing.

FIGS. 8-9 illustrate erosion rates for thin film protective layers formed in accordance with embodiments of the present invention. FIG. 8 shows erosion rates of thin film protective layers when exposed to a CH₄/Cl₂ plasma chemistry. As shown, the IAD deposited thin film protective layers show a much improved erosion resistance as compared to Al₂O₃. For example, alumina with a 92% purity showed an erosion rate of around 18 nanometers pre radiofrequency hour (nm/RFHr) and alumina with a 99.8% purity showed an erosion rate of about 56 nm/RFHr. In contrast an IAD deposited compound ceramic thin film protective layer showed an erosion rate of about 3 nm/RFHr and an IAD deposited YAG thin film protective layer showed an erosion rate of about 1 nm/RFHr.

FIG. 9 shows erosion rates of thin film protective layers when exposed to a H₂/NF₃ plasma chemistry. As shown, the IAD deposited thin film protective layers show a much improved erosion resistance as compared to Al₂O₃. For example, alumina with a 92% purity showed an erosion rate of around 190 nm/RFHr and alumina with a 99.8% purity showed an erosion rate of about 165 nm/RFHr. In contrast an IAD deposited YAG thin film protective layer showed an erosion rate of about 52 nm/RFHr. Similarly, a compound ceramic thin film protective layer deposited using IAD with low energy ions showed an erosion rate of about 45 nm/RFHr and a compound ceramic thin film protective layer deposited using IAD with high energy ions showed an erosion rate of about 35 nm/RFHr. An EAG thin film protective layer deposited using IAD with high deposition temperature (e.g., around 270° C.) showed an erosion rate of about 95 nm/RFHr and an EAG thin film protective layer deposited using IAD with low deposition temperature (e.g., around 120-150° C.) showed an erosion rate of about 70 nm/RFHr. An Er₂O₃ thin film protective layer deposited using IAD with high energy ions showed an erosion rate of about 35 nm/RFHr.

FIGS. 10-11 illustrate roughness profiles for thin film protective layers formed in accordance with embodiments of the present invention. FIG. 10 shows surface roughness profiles of thin film protective layers of FIG. 8 before and after exposure to a CH₄/Cl₂ plasma chemistry for 100 RFHrs. As shown, the IAD deposited thin film protective layers show a minimum change in surface roughness after exposure to a CH₄/Cl₂ plasma chemistry for 100 RFHrs.

FIG. 11 shows surface roughness profiles of thin film protective layers of FIG. 9 before and after exposure to an H₂/NF₃ plasma chemistry for 35 RFHrs. As shown, the IAD deposited thin film protective layers show a minimum change in surface roughness after exposure to an H₂/NF₃ plasma chemistry for 35 RFHrs.

FIG. 12 shows erosion rates of various materials exposed to a CF₄—CHF₃ trench chemistry at low bias, including erosion rates of multiple different IAD coatings generated in accordance with embodiments described herein. As shown, an erosion rate of 92% Alumina is around 0.26 microns per radiofrequency hour (μm/Rfhr), an erosion rate of IAD deposited EAG is around 0.18 μm/Rfhr, an erosion rate of IAD deposited YAG is about 0.15 μm/Rfhr, an erosion rate of the plasma spray deposited compound ceramic is about 0.09 μm/Rfhr, an erosion rate of IAD deposited Y₂O₃ is about 0.08 μm/Rfhr, an erosion rate of IAD deposited ceramic compound is about 0.07 μm/Rfhr, an erosion rate of bulk Y₂O₃ is about 0.07 μm/Rfhr, an erosion rate of a bulk ceramic compound is about 0.065 μm/Rfhr, and an erosion rate of IAD deposited Er₂O₃ is about 0.05 μm/Rfhr. Similar etch results occur when these materials are etched using a CF₄—CHF₃ trench chemistry at a high bias. For example, at a high bias an etch rate of 92% Alumina is around 1.38 μm/Rfhr, an erosion rate of IAD deposited EAG is around 0.27 μm/Rfhr, an erosion rate of IAD deposited YAG is about 0.27 μm/Rfhr, an erosion rate of the plasma spray deposited compound ceramic is about 0.35 μm/Rfhr, an erosion rate of IAD deposited Y₂O₃ is about 0.18 μm/Rfhr, an erosion rate of IAD deposited ceramic compound is about 0.19 μm/Rfhr, an erosion rate of bulk Y₂O₃ is about 0.4 μm/Rfhr, an erosion rate of a bulk ceramic compound is about 0.4 μm/Rfhr, and an erosion rate of IAD deposited Er₂O₃ is about 0.18 μm/Rfhr.

TABLE 4 Metal Contamination Results Detection Limit Specification Test 1 Test 2 Element (atom/cm²) (atom/cm²) (atom/cm²) (atom/cm²) Al 0.1 <100 3.2 98 Y 0.01 <100 0.02 46 Ni 0.03 <10 0.22 0.042 Fe 0.05 <10 0.47 2.5 Cr 0.03 <10 0.17 1.0 Cu 0.01 <10 <0.01 0.31 Ti 0.03 <10 <0.03 0.13 Ca 0.10 <10 <0.1 4.2

Lids and nozzles coated with IAD deposited thin film protective layers formed in accordance with embodiments of the present invention have metal contamination results that meet the indicated specification shown in Table 4. The table identifies metal contaminant elements, a detection limit, a specification limit, a first test result and a second test result. The detection limit is the minimum detectable level of contamination. The specification limit is atoms per square centimeter (atom/cm²) found on a substrate (e.g., a wafer) that is processed in the tests. As shown, in two distinct metal contamination tests the level of aluminum and yttrium contamination was less than 100 atoms/cm², and the level of nickel, iron, chromium, copper, titanium and calcium contamination was less than 10 atoms/cm². For each of the tests a lid and nozzle including a thin film protective layer of the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂ was used during a test process. The level of metal contamination was measured after each test process. Similar contamination results are achievable using other IAD deposited thin film protective layers formed in accordance with embodiments described herein.

After 100 RFhr of processing using a lid and nozzle having a thin film protective layer of the ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, overall particle contamination on a processed 300 mm wafer was tested to be about 50 particles greater than 65 nm in size, about 40 particles greater than 90 nm in size, and about 20 particles greater than 165 nm in size. The measured particle contamination is the total number of particles above a given size on a 300 mm wafer. After 50 RFhr of processing, overall particle contamination was tested to be about 40 particles greater than 65 nm in size, about 30 particles greater than 90 nm in size, and about 18 particles greater than 165 nm in size.

The preceding description sets forth numerous specific details such as examples of specific systems, components, methods, and so forth, in order to provide a good understanding of several embodiments of the present invention. It will be apparent to one skilled in the art, however, that at least some embodiments of the present invention may be practiced without these specific details. In other instances, well-known components or methods are not described in detail or are presented in simple block diagram format in order to avoid unnecessarily obscuring the present invention. Thus, the specific details set forth are merely exemplary. Particular implementations may vary from these exemplary details and still be contemplated to be within the scope of the present invention.

Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, the appearances of the phrase “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. In addition, the term “or” is intended to mean an inclusive “or” rather than an exclusive “or.” When the term “about” or “approximately” is used herein, this is intended to mean that the nominal value presented is precise within ±30%.

Although the operations of the methods herein are shown and described in a particular order, the order of the operations of each method may be altered so that certain operations may be performed in an inverse order or so that certain operation may be performed, at least in part, concurrently with other operations. In another embodiment, instructions or sub-operations of distinct operations may be in an intermittent and/or alternating manner.

It is to be understood that the above description is intended to be illustrative, and not restrictive. Many other embodiments will be apparent to those of skill in the art upon reading and understanding the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. 

What is claimed is:
 1. A component for a semiconductor processing chamber, comprising: a ceramic body having at least one surface with a first average surface roughness of approximately 8-16 micro-inches; and a conformal protective layer on at least one surface of the ceramic body, wherein the conformal protective layer is a plasma resistant rare earth oxide film having a substantially uniform thickness of less than 300 μm over the at least one surface and having a second average surface roughness of below 10 micro-inches, wherein the second average surface roughness is equal to or less than the first average surface roughness.
 2. The component of claim 1, wherein the conformal protective layer comprises at least one of Y₄Al₂O₉ or YF₃.
 3. The component of claim 1, wherein the conformal protective layer has a thickness of 10-30 μm and a porosity of below 1%.
 4. The component of claim 1, wherein the average surface roughness of the conformal protective layer is less than 8 micro-inches and the substantially uniform thickness of the conformal protective layer is about 0.5-7.0 μm.
 5. The component of claim 1, wherein the ceramic body is a bulk sintered ceramic body comprising at least one of Y₂O₃ or a ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂.
 6. The component of claim 1, where the conformal protective layer comprises a protective layer stack comprising a plurality of plasma resistant rare earth oxide films comprising a first plasma resistant rare earth oxide film on the at least one surface and a second plasma resistant rare earth oxide film on the first plasma resistant rare earth oxide film, wherein each of the plurality of plasma resistant rare earth oxide films has a thickness of less than 20 microns.
 7. The component of claim 1, wherein the ceramic body is a disc shaped body that has a diameter of at least 12 inches, and wherein a curvature of a lower surface of the ceramic body is less than about 50 microns over the lower surface.
 8. The component of claim 1, wherein the component is usable at temperatures of about 0-1000° C. without the conformal protective layer cracking due to thermal shock.
 9. The component of claim 1, wherein the conformal protective layer comprises crystalline Er₃Al₅O₁₂ having a dielectric constant of 7-12, a thermal conductivity of 14-25 W/m·K, a hermiticity of 4E-9 to 7E-9 cm³/s, a hardness of 5-6 GPa, a wear rate of 0.8-0.14 nm per hour, an erosion rate of about 0.24 μm per hour to a CF₄ etch chemistry, and an erosion rate of about 95 nm per hour to an H₂/NF₃ plasma chemistry.
 10. The component of claim 1, wherein the component is a lid, the lid further comprising: a hole approximately at a center of the lid, wherein the conformal protective layer covers at least a portion of a wall of the hole, and wherein the conformal protective layer is thicker near the at least one surface of the lid and gradually becomes thinner deeper into the hole.
 11. The component of claim 1, wherein the component is a lid, the lid further comprising: a lip on the at least one surface at an outer perimeter of the lid that is to be in contact with walls of a chamber when the lid is closed, wherein the conformal protective layer does not cover the lip.
 12. A chamber component for a processing chamber comprising: a ceramic body having at least one surface with a first average surface roughness of approximately 8-16 micro-inches; and a conformal protective layer on the at least one surface of the ceramic body, wherein the conformal protective layer is a plasma resistant rare earth oxide film selected from a group consisting of a first ceramic compound comprising a mixture of Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, and a second ceramic compound comprising a mixture of Y₂O₃, ZrO₂, Er₂O₃, Gd₂O₃ and SiO₂, the conformal protective layer having a substantially uniform thickness of less than 300 μm over the at least one surface and having a second average surface roughness of below 10 micro-inches, wherein the second average surface roughness is equal to or less than the first average surface roughness.
 13. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 40 mol % to below 100 mol % of Y₂O₃, above 0 mol % to 60 mol % of ZrO₂, and above 0 mol % to 10 mol % of Al₂O₃.
 14. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 40 mol % to 60 mol % of Y₂O₃, 30 mol % to 50 mol % of ZrO₂, and 10 mol % to 20 mol % of Al₂O₃.
 15. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 40 mol % to 50 mol % of Y₂O₃, 20 mol % to 40 mol % of ZrO₂, and 20 mol % to 40 mol % of Al₂O₃.
 16. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 70 mol % to below 90 mol % of Y₂O₃, above 0 mol % to 20 mol % of ZrO₂, and 10 mol % to 20 mol % of Al₂O₃.
 17. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 60 mol % to below 80 mol % of Y₂O₃, above 0 mol % to 10 mol % of ZrO₂, and 20 mol % to 40 mol % of Al₂O₃.
 18. The component of claim 12, wherein the conformal protective layer comprises the first ceramic compound comprising Y₄Al₂O₉ and a solid-solution of Y₂O₃—ZrO₂, wherein the first ceramic compound comprises 40 mol % to below 60 mol % of Y₂O₃, above 0 mol % to 20 mol % of ZrO₂, and 30 mol % to 40 mol % of Al₂O₃.
 19. A chamber component for a processing chamber comprising: a ceramic body having at least one surface with a first average surface roughness of approximately 8-16 micro-inches; and a conformal protective layer on the at least one surface of the ceramic body, wherein the conformal protective layer is a plasma resistant rare earth oxide film selected from a group consisting of Er₂O₃, Er₄Al₂O₉, or ErAlO₃, the conformal protective layer having a substantially uniform thickness of less than 300 μm over the at least one surface and having a second average surface roughness of below 10 micro-inches, wherein the second average surface roughness is equal to or less than the first average surface roughness.
 20. The chamber component of claim 19, wherein the conformal protective layer comprises Er₂O₃ and the ceramic body comprises Al₂O₃, the component further comprising: a transition layer between the conformal protective layer and the ceramic body, wherein the transition layer comprises Er₃Al₅O₁₂. 